The “New Core Paradox”: Challenges and Potential Solutions

The “new core paradox” suggests that the persistence of the geomagnetic field over nearly all of Earth history is in conflict with the core being highly thermally conductive, which makes convection and dynamo action in the core much harder prior to the nucleation of the inner core. Here we revisit t...

Full description

Saved in:
Bibliographic Details
Published in:Journal of geophysical research. Solid earth 2023-01, Vol.128 (1), p.n/a
Main Authors: Driscoll, P., Davies, C.
Format: Article
Language:English
Subjects:
Convection
Cooling
core
Earth
Earth core
Earth history
Earth mantle
Earth motion
Entropy
Estimates
Evolution
Ferrous alloys
Fluid motion
geodynamo
Geological time
Geology
Geomagnetic field
Geomagnetism
Geophysics
Heat conductivity
Heat flow
Heat transfer
Heat transmission
Heating rate
Iron
Liquidus
Lower mantle
Mathematical models
Melt temperature
Melting
Modelling
Nucleation
Palaeomagnetism
Paleomagnetism
Paradoxes
Parameters
Planet formation
Radioactivity
Temperature
Thermal conductivity
thermal evolution
Viscosity
Viscosity ratio
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The “new core paradox” suggests that the persistence of the geomagnetic field over nearly all of Earth history is in conflict with the core being highly thermally conductive, which makes convection and dynamo action in the core much harder prior to the nucleation of the inner core. Here we revisit this issue by exploring the influence of six important parameters on core evolution: upper/lower mantle viscosity ratio, core thermal conductivity, core radiogenic heat rate, mantle radiogenic heating rate, central core melting temperature, and initial core‐mantle boundary (CMB) temperature. Each parameter is systematically explored by the model, which couples mantle energy and core energy‐entropy evolution. A model is “successful” if the correct present‐day inner core size is achieved and the dynamo remains alive, as implied by the paleomagnetic record. In agreement with previous studies, we do not find successful thermal evolutions using nominal parameters, which includes a core thermal conductivity of 70 Wm−1K−1, zero core radioactivity, and an initial CMB temperature of 5,000 K. The dynamo can be kept alive by assuming an unrealistically low thermal conductivity of 20 Wm−1K−1 or an unrealistically high core radioactive heat flow of 3 TW at present‐day, which are considered “unsuccessful” models. We identify a third scenario to keep the dynamo alive by assuming a hot initial CMB temperature of ∼6,000 K and a central core liquidus of ∼5,550 K. These temperatures are on the extreme end of typical estimates, but should not be ruled out and deserve further scrutiny. Plain Language Summary The cooling of Earth over geological time is of interest to many scientific disciplines and has been studied intensively. Maintaining the geomagnetic field requires continuous core cooling to drive fluid motion in Earth's liquid iron outer core. Recent studies have shown that the materials that make up Earth's core can conduct heat very efficiently, which makes fluid motion in the core more difficult. In this study we investigate the thermal and magnetic evolution of Earth using a core‐mantle cooling model. In particular, we investigate how several important aspects of Earth's interior that control its thermal and magnetic evolution over 4.5 billion years. In agreement with previous studies, we confirm that typical models fail to reproduce the thermal and magnetic evolution found in the geological record. We identify a potentially new solution that invokes (a) that the core is in
ISSN:2169-9313
2169-9356
DOI:10.1029/2022JB025355